private void init(int n)
{
this.n = n;
this.stop = new GeneralConvergence(n);
nelderMead = new NelderMead(nsmax, subspace_func);
nelderMead.Convergence = this.stop;
xstep = new double[n];
xstep0 = new double[n];
for (int i = 0; i < xstep0.Length; i++)
{
xstep0[i] = 1e-5;
}
p = new int[n];
dx = new double[n];
xprev = new double[n];
absdx = new double[n];
lb = new double[n];
for (int i = 0; i < lb.Length; i++)
{
lb[i] = Double.NegativeInfinity;
}
ub = new double[n];
for (int i = 0; i < ub.Length; i++)
{
ub[i] = Double.PositiveInfinity;
}
}
NelderMeadStatus sbplx_minimize()
{
var ret = NelderMeadStatus.Success;
double[] x = Solution;
Value = Function(x);
this.stop.Evaluations++;
if (NelderMead.nlopt_stop_forced(stop))
{
return(NelderMeadStatus.ForcedStop);
}
if (Value < this.minf_max)
{
return(NelderMeadStatus.MinimumAllowedValueReached);
}
if (NelderMead.nlopt_stop_evals(stop))
{
return(NelderMeadStatus.MaximumEvaluationsReached);
}
if (NelderMead.nlopt_stop_time(stop))
{
return(NelderMeadStatus.MaximumTimeReached);
}
Array.Copy(xstep0, xstep, xstep.Length);
while (true)
{
double normi = 0;
double normdx = 0;
int ns, nsubs = 0;
int nevals = this.stop.Evaluations;
double fdiff, fdiff_max = 0;
Array.Copy(x, xprev, x.Length);
double fprev = Value;
// sort indices into the progress vector dx
// by decreasing order of magnitude abs(dx)
//
for (int i = 0; i < p.Length; i++)
{
p[i] = i;
}
for (int j = 0; j < absdx.Length; j++)
{
absdx[j] = Math.Abs(dx[j]);
}
Array.Sort(p, absdx);
// find the subspaces, and perform nelder-mead on each one
for (int i = 0; i < absdx.Length; i++)
{
normdx += absdx[i]; // L1 norm
}
int last = 0;
for (int i = 0; i + nsmin < n; i += ns)
{
last = i;
// find subspace starting at index i
double ns_goodness = -Double.MaxValue;
double norm = normi;
int nk = i + nsmax > n ? n : i + nsmax; // max k for this subspace
for (int k = i; k < i + nsmin - 1; k++)
{
norm += absdx[p[k]];
}
ns = nsmin;
for (int k = i + nsmin - 1; k < nk; k++)
{
double goodness;
norm += absdx[p[k]];
// remaining subspaces must be big enough to partition
if (n - (k + 1) < nsmin)
{
continue;
}
// maximize figure of merit defined by Rowan thesis:
// look for sudden drops in average |dx|
if (k + 1 < n)
{
goodness = norm / (k + 1) - (normdx - norm) / (n - (k + 1));
}
else
{
goodness = normdx / n;
}
if (goodness > ns_goodness)
{
ns_goodness = goodness;
ns = (k + 1) - i;
}
}
for (int k = i; k < i + ns; ++k)
{
normi += absdx[p[k]];
}
// do nelder-mead on subspace of dimension ns starting w/i
sindex = i;
for (int k = i; k < i + ns; ++k)
{
nelderMead.Solution[k - i] = x[p[k]];
nelderMead.StepSize[k - i] = xstep[p[k]];
nelderMead.LowerBounds[k - i] = lb[p[k]];
nelderMead.UpperBounds[k - i] = ub[p[k]];
}
nsubs++;
nevals = this.stop.Evaluations;
nelderMead.NumberOfVariables = ns;
nelderMead.DiameterTolerance = psi;
ret = nelderMead.Minimize(Value);
fdiff = nelderMead.Difference;
Value = nelderMead.Value;
if (fdiff > fdiff_max)
{
fdiff_max = fdiff;
}
Trace.WriteLine(String.Format("{0} NM iterations for ({1},{2}) subspace",
this.stop.Evaluations - nevals, sindex, ns));
for (int k = i; k < i + ns; k++)
{
x[p[k]] = nelderMead.Solution[k - i];
}
if (ret == NelderMeadStatus.Failure)
{
return(NelderMeadStatus.SolutionToleranceReached);
}
if (ret != NelderMeadStatus.SolutionToleranceReached)
{
return(ret);
}
}
// nelder-mead on last subspace
ns = n - last;
sindex = last;
for (int i = last; i < n; i++)
{
nelderMead.Solution[i - sindex] = x[p[i]];
nelderMead.StepSize[i - sindex] = xstep[p[i]];
nelderMead.LowerBounds[i - sindex] = lb[p[i]];
nelderMead.UpperBounds[i - sindex] = ub[p[i]];
}
nsubs++;
nevals = this.stop.Evaluations;
nelderMead.NumberOfVariables = ns;
nelderMead.DiameterTolerance = psi;
ret = nelderMead.Minimize(Value);
fdiff = nelderMead.Difference;
Value = nelderMead.Value;
if (fdiff > fdiff_max)
{
fdiff_max = fdiff;
}
Trace.WriteLine(String.Format("sbplx: {0} NM iterations for ({1},{2}) subspace",
this.stop.Evaluations - nevals, sindex, ns));
for (int i = sindex; i < p.Length; i++)
{
x[p[i]] = nelderMead.Solution[i - sindex];
}
if (ret == NelderMeadStatus.Failure)
{
return(NelderMeadStatus.SolutionToleranceReached);
}
if (ret != NelderMeadStatus.SolutionToleranceReached)
{
return(ret);
}
// termination tests:
if (NelderMead.nlopt_stop_ftol(stop, Value, Value + fdiff_max))
{
return(NelderMeadStatus.FunctionToleranceReached);
}
if (NelderMead.nlopt_stop_xtol(stop, x, xprev, n))
{
int j;
// as explained in Rowan's thesis, it is important
// to check |xstep| as well as |x-xprev|, since if
// the step size is too large (in early iterations),
// the inner Nelder-Mead may not make much progress
//
for (j = 0; j < xstep.Length; j++)
{
if (Math.Abs(xstep[j]) * psi > stop.AbsoluteParameterTolerance[j] &&
Math.Abs(xstep[j]) * psi > stop.RelativeParameterTolerance * Math.Abs(x[j]))
{
break;
}
}
if (j == n)
{
return(NelderMeadStatus.SolutionToleranceReached);
}
}
// compute change in optimal point
for (int i = 0; i < x.Length; i++)
{
dx[i] = x[i] - xprev[i];
}
// setting step sizes
{
double scale;
if (nsubs == 1)
{
scale = psi;
}
else
{
double stepnorm = 0, dxnorm = 0;
for (int i = 0; i < dx.Length; i++)
{
stepnorm += Math.Abs(xstep[i]);
dxnorm += Math.Abs(dx[i]);
}
scale = dxnorm / stepnorm;
if (scale < omega)
{
scale = omega;
}
if (scale > 1 / omega)
{
scale = 1 / omega;
}
}
Trace.WriteLine("sbplx: stepsize scale factor = " + scale);
for (int i = 0; i < xstep.Length; i++)
{
xstep[i] = (dx[i] == 0) ?
-(xstep[i] * scale) : Special.Sign(xstep[i] * scale, dx[i]);
}
}
}
}